Write and read collision avoidance in single port memory devices

ABSTRACT

A method of avoiding a write collision in single port memory devices from two independent write operations is described. A first data object from a first write operation is divided into a first even sub-data object and first odd sub-data object. A second data object from a second write operation is divided into a second even sub-data object and a second odd sub-data object. The first even sub-data object is stored to a first single port memory device and the second odd sub-data object to a second single port memory device when the first write operation and the second write operation occur at the same time. The second even sub-data object is stored to the first single port memory device and the first odd sub-data object to the second single port memory device when the first write operation and the second write operation occur at the same time.

BACKGROUND

This invention relates generally to single port memory device, and more particularly, to write and read collision avoidance system in single port memory device.

Single port memory devices may allow only one write or read operation at a time. Examples, of single port memory devices may include static random access memory (SRAM), dynamic random access memory (DRAMs), or the like. SRAM is a volatile memory where any data stored is erased when the power supply to the SRAM is turned off. An SRAM cell is often made up of six transistors. Four transistors make up a cross-coupled latch that either stores a logical one or a logical zero. The other two transistors are used for accessing the SRAM cell during read and write operations. Access speed for SRAM is fast compared to certain other memories and so therefore is often used as cache memory and for buffers. Single port memory devices such as SRAM are often used as buffers between two asynchronous circuits.

SUMMARY

In an embodiment, a method of avoiding a write collision in single port memory devices from two or more independent write operations is described. A first data object from a first write operation is divided into a first even sub-data object and a first odd sub-data object. A second data object from a second write operation is divided into a second even sub-data object and a second odd sub-data object. The first even sub-data object is stored in a single write to a first single port memory device and the second odd sub-data object to a second single port memory device when the first write operation and the second write operation occur substantially at the same time. The second even sub-data object is stored with a single write to the first single port memory device and the first odd sub-data object to the second single port memory device when the first write operation and the second write operation occur substantially at the same time.

In another embodiment, a semiconductor chip is described that includes a module. The module includes a first single port memory device configured to store a first even sub-data object and a second even sub-data object. The module is further includes a second single port memory device configured to store a first odd sub-data object and a second odd sub-data object. The module also includes a serializer. The serializer is configured to divide a first data object from a first write operation into a first even sub-data object and a first odd sub-data object. The serializer is further configured to divide a second data object from a second write operation into a second even sub-data object and a second odd sub-data object. The serializer further can store, in a single write, the first even sub-data object to the first single port memory device and the second odd sub-data object to the second single port memory device when the first write operation and the second write operation occur substantially at the same time. Also, the serializer is configured to store, in a single write, the second even sub-data object to the first single port memory device and the first odd sub data object to the second single port memory device when the first write operation and the second write operation occur substantially at the same time.

In yet another embodiment, a method of avoiding read collisions from single port memory devices from two or more independent read operation requests is described. A first read request for a first data object from a first read requester is received. A second read request for a second data object from a second read requester is received at substantially the same time as the first read request. A first even sub-data object of the first data object from a first single port memory device is read. A second odd sub-data object of the second data object from a second single port memory device is read at substantially the same time as reading the first even sub-data object. A first odd sub-data object of the first data object from the second single port memory device is read. A second even sub-data object of the second data object is read from the first single port memory device at substantially the same time as reading the first odd sub-data object. The first even sub-data object and the first odd sub-data object are combined to form the first data object. The second even sub-data object and the first odd sub-data object are combined to form the second data object.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments will be better understood from the following detailed description with reference to the drawings, in which:

FIG. 1 illustrates a block diagram of a semiconductor chip on which a module supporting single port memory device is configured to avoid write collision and read collisions, according to embodiments.

FIG. 2 illustrates a block diagram of a module on which the single port memory device is located and the module configured to avoid write and read collisions on the single port memory device, according to embodiments.

FIG. 3 illustrates a timing chart of the flow of data objects through the module of FIG. 2, according to embodiments.

FIG. 4 illustrates a flowchart for avoiding write collision in a single port memory device, according to embodiments.

FIG. 5 illustrates a block diagram of a module on which the single port memory device is configured to avoid write collisions of data objects where the data objects are not divided into sub-data objects, according to embodiments.

FIG. 6 illustrates launch logic of a data sender sending a write operation, according to embodiments.

FIG. 7 illustrates a timing chart of the flow of the data objects through a module, such as a module of FIG. 5, according to embodiments.

FIG. 8 illustrates a flowchart of a method for avoiding a write collision in a single port memory device in a module, such as a module of FIG. 5, according to embodiments.

FIG. 9 illustrates read operation circuitry for the module of FIG. 5, according to various embodiments.

DETAILED DESCRIPTION

Features illustrated in the drawings are not necessarily drawn to scale. Descriptions of well-known components and processing techniques are omitted so as to not unnecessarily obscure the disclosed embodiments. The descriptions of embodiments are provided by way of example only, and are not intended to limit the scope of this invention as claimed. The same numbers may be used in the Figures and the Detailed Description to refer to the same devices, parts, components, steps, operations, and the like.

Embodiments herein provide for a semiconductor chip and method of avoiding single port memory device write collisions from two or more data object senders performing write operations that may occur at the same time resulting in the write collision. Avoiding write collisions may be done by dividing a data object of a write operation into two or more sub-data objects. The division may occur for each write operation and each sub-data object of a write operation may have a dedicated single port memory device. Each dedicated single port memory device may store a type of sub-data object from each write operation. This allows write operations arriving to the single port memory devices at the same time to write a first type sub-data object from a first write operation to a first single port memory device at the same time as a second type sub-data object from a second write operation writes to a second single port memory device. In embodiments, the data objects may be aligned and delayed as necessary of the purpose of preventing write collisions on the same single port memory device by dedicating a first single port memory device to even data objects and a second single port memory device to odd data objects.

Other embodiments include storing even data objects to a first single port memory and odd data objects to a second single port memory at substantially the same time. The even and odd data object from two or more senders may be interleaved when storing to the single port memories so as not to create a write collision. Yet other embodiments herein provide for a semiconductor chip and a method of avoiding single port memory read collisions to two or more read requesters from the single port memories.

In certain read/write environments for single port memory devices, write collisions may occur. Write collisions may occur when two or more write operations arrive at substantially the same time in the single port memory device. Write collisions may produce errors in an operation trying to be performed. The single port memory devices may receive two or more write operations because they may be receiving write operations from two or more independent sources that share the resources of the single port memory device. Sharing single port memory devices may be advantageous for multiple reasons such as for reduced power and size restrictions.

Not only may there be write collisions in single port memory devices but read collisions may also occur. Read collisions may occur when there are multiple read requesters requesting data objects from a shared single port memory at substantially the same time. Read collisions may also produce errors in an operation trying to be performed.

Aspects of the present disclosure are based upon the recognition that write collisions in single port memory device can be accounted for by using a multiport memory that allows writes to more than one row of the memory at the same time. Each write operation source may have a dedicated write port, which would allow the writing to different rows of the memory at the same time. However, multiport memories can be more expensive than the single port memory devices in the terms of power, area, testability, yield, and development effort. Another recognition for avoiding write collisions in single port memory device is to use twice as many single port memory devices when there are multiple write operations from independent sources. Each source would get its own dedicated single port memory device set. Additional control logic may be used to keep track of which write source owns the actual single port memory device. Doubling the amount of single port memory devices also doubles the cost in terms of power, area, and yield. These recognitions also contemplate avoidance of read collisions due to their nature of avoiding write collisions (multiport and doubled amount of single port memory).

An example of the situation where write collisions may occur in single port memory devices is on a computer processor chip or other semiconductor chip. A data sender (also referred to as a write source herein) on the processor chip, such as level three (L3) cache, may be split into two, which allows for a first and second write operation from two independent write sources, e.g. the first L3 cache and a second L3 cache. The split L3 cache may be connected to a module containing single port memory devices such as a PCI bridge controller. The PCI bridge controller may include a dedicated buffer for each I/O fetch finite state machine (FSM) that fetches a data object from the L3 cache. Each buffer may have a capacity of 256 bytes. The buffers are not all written to at once but at 16 bytes at a 4:1 cycle. There may be a total of 32 buffers in the example module. For efficient power and area reasons, multiple buffers may share a single port memory device such as SRAM or DRAM. Four buffers may be in each SRAM for a total of eight SRAMs used. Buffers within a SRAM may be associated with fetches to either of the L3 caches created by the split. The two L3 caches are independent and responses with data objects may arrive at any time. When two fetch responses (also referred to as write operations) for two buffers sharing the same single port SRAM arrive from the first L3 cache and the second L3 cache at the same time, a write collision may occur.

FIG. 1 illustrates a block diagram of a semiconductor chip 100 on which a module 115 supporting a single port memory device 120 is configured to avoid write collisions, according to embodiments of the present disclosure. The semiconductor chip 100 may be a computer processing chip, for example. The semiconductor chip 100 may include one or more processor cores, collectively referenced as 105. FIG. 1 illustrates four cores 105 a, 105 b, 105 c, and 105 d. The semiconductor chip 100 may include a first data sender 110 a and a second data sender 110 b, collectively referenced as data senders 110 herein. The data senders 110 may be a cache such as an L3 cache, in an embodiment. Each data sender 110 may be shared by the cores 105. The data senders 110 that communicate with a module 115 may send write operations to the module 115. The module 115 may include one or more single port memory devices (SPM) 120. The module 115 may be a peripheral component interconnect (PCI) bridge controller, however, other modules that include single port memory devices 120 may be considered. The module 115 may output to one or more read requesters. In embodiments, multiple semiconductor chips may be used to contain the referenced components.

Embodiments herein may provide for the module 115 to be configured to allow write operations from the data senders 110 to the single port memory device 120 without write collisions. Avoiding write collisions may be done by dividing a data object of a write operation from a data sender 110 into two or more sub-data objects. The division may occur for each write operation and each sub-data object of a write operation may have a dedicated single port memory device 120. Each dedicated single port memory device 120 stores a type of sub-data object from each write operation. This allows write operations arriving to the single port memory devices 120 at the same time to write a first type sub-data object from a first write operation to a first single port memory device at the same time as a second type sub-data object from a second write operation writes to a second single port memory device. In embodiments, the data objects may be aligned and delayed as necessary of the purpose of preventing write collisions on the same single port memory device by dedicating a first single port memory device to even data objects and a second single port memory device to odd data objects. When there is a data request from a single data requester, the module 115 may output the even and odd sub-data objects of the data object in parallel to combine into a whole data object. In other embodiments, when there are two or more data object requests at the same time from two or more read requesters, the module 115 may be configured to send both data objects without resulting in a read collision.

FIG. 2 illustrates a block diagram of a module 115 in which the single port memory device 120 is located and where the module 115 is configured to avoid write collisions and read collisions on the single port memory device 120, according to embodiments. Consistent with certain embodiments, the module 115 may include a serializer for each write operation such as serializers 205 a and 205 b, collectively referred to as serializer 205. The module 115 may include a plurality of single port memory devices 120 (120 a, 120 b, 120 c, and 120 d), a write controller 215, a read controller 220, a write circuitry 225 and a read circuitry 230. A first write operation may come from a first data sender 110 a such as a cache or any other circuit that may produce a write operation. A second write operation may come from a second data sender 110 b such as a cache or any other circuit that may produce a write operation. The first write operation may produce a first data object. The second write operation may produce a second data object. A data object may be the natural width of an interface bus between the data sender 110 and the single port memory devices 120. In the case of a write operation from L3 cache to a PCI bridge controller, the data object may be 16 bytes, for example.

Once received by the module 115 from the data sender 110, the first data object may enter a first serializer 205 a. The second data object may enter a second serializer 205 b. The serializers 205 may divide the data objects into multiple sub-data objects. In the illustrated example, the serializers 205 may be 2:1 serializers, which may require that the single port memory device operate at twice the speed of regular bus speed. The serializers 205 may divide the data objects in half into even and odd sub-data objects. This may produce a first even sub-data object and first odd sub-data object from the first data object. A second even sub-data object and a second odd sub-data object may be created by the second serializer 205 b from the second data object. In the given example, the 16 byte data objects may be divided into 8 byte sub-data objects. The even sub-data object may be sent to a first single port memory device dedicated for even sub-data objects and the odd sub-data objects may be sent to a second single port memory device dedicated for odd sub-data objects.

The sub-data objects may be written to a plurality of single port memory devices 120. In an embodiment, the single port memory devices 120 may be SRAM. Each single port memory device 120 may be designated for either an even sub-data object or an odd sub-data object. Each single port memory device 120 may contain a plurality of buffers. Single port memory devices 120 a and 120 b may include eight buffers. Half of each buffer may be in each single port memory device 120 a and 120 b. For instance, single port memory device 120 a may include the even buffer (0) for the even sub-data object and single port memory device 120 b may include odd buffer (0) for the odd portion of the data object. Write circuitry 225 may regulate the sub-data objects entering the single port memory devices 120 as shown with exemplary write multiplexors 240. A write controller 215 may be interconnected with the single port memory devices 120 in order to provide a write enable signal and a write address to the single port memory devices. The write controller may be in operable communication with the data senders 110. The data senders 110 may single the write controller 215 when to perform a write. The write controller 215 may also be in communication to each write multiplexor 240 (the write controller 215 is in communication with write circuitry 225 in FIG. 2 for clarity of the figure) to steer the sub-data objects.

For each write enable cycle to the single port memory devices 120, a write operation may be set up to only write either an odd sub-data object or an even sub-data object. This may be done so that the first write operation is not equally aligned with the second write operation. In the illustrated example, the first data sender 110 a may write an even sub-data object while the second data sender 110 b writes an odd-data object. This arrangement may ensure that no single port memory device write collisions occur. This is because while an even sub-data object is being written to first single port memory device 120 a from the first data sender 110 a, an odd sub-data object is being written to a second single port memory device 120 b from the second sender 110 b and vice versa when an odd sub-data object is being written from the first data sender 110 b.

When the data objects are to be retrieved from the single port memory devices 120, a read controller 220 may manage the read operations that obtain the sub-data objects. The read controller 220 may be interconnected with each of the single port memory devices 120. The read controller 220 may be used to provide a read enable signal and a read address to the single port memory devices 120. The read controller 220 may receive read requests from one or more read requesters 250 a and 250 b. The read controller 220 may also be in communication with the read circuitry 230. The read controller 220 may control the demultiplexors 245 and the deserializers 235 a and 235 b of the read circuitry 230 for proper reads. There may be a plurality of read requesters that may request one or more data objects at the same time, which may result in a read collision. FIG. 2 illustrates embodiments of read circuitry 230 when there are two read requesters. In various embodiments, one read may occur at a time from one read requester. FIG. 5 illustrates read circuitry 545, explained further below, which may be used for the module 115 in place of the read circuitry 230 when there is one read requester. When there is one read requester, the odd and even sub-data objects may be retrieved or sent from the single port memory devices 120 for either the first or second data objects. The odd and even sub-data objects may be retrieved in parallel to form the complete first or second data object depending on which data object is requested.

In other embodiments, there may be two read requesters as illustrated in FIG. 2. There may be a first read request for a data object from a first read requester 250 a at the same time as a second request from a second read requester 250 b for a data object stored in at least one same single port memory. This may cause a read collision similar to the write collisions explained above. The single port memories 120 may be communication to a respective demultiplexor 245. Each demultiplexor 245 may be in communication with a first deserializer 235 a and a second deserializer 235 b. The read controller 220 may manage the outputs of the demultiplexors 245 and the deserializers 235 a and 235 b. The first read requester 250 a may be coupled to an output of the first deserializer 235 a and the second read requester 250 b may be coupled to an output of the second deserializer 235 b. Both read requesters may be coupled to the read controller 220 for signaling reads.

In various embodiments, the first and second data objects may be stored in at least one of the same single port memories, which may be single port memory 120 a for even sub-data objects and single port memory 120 b for odd sub-data objects. The first read requester may request the first data object at the same time as the second requester requests the second data object. If two read requests occur, then read controller 220 of module 115 may direct the first even-sub data object of the first data object from the even single port memory 120 a to be sent to the first deserializer 235 a. Also, the second odd sub-data object of the second data object from the odd single port memory 120 b may be sent to the second deserializer 235 b. This may all occur at a first half cycle of the read. During the second half cycle of the read, the read controller 220 of module 115 may direct the second even-sub data object of the second data object from the even single port memory 120 a to be sent to the second deserializer 235 b. Also, the first odd-sub data object of the first data object from the even single port memory 120 a may be sent to the first deserializer 235 a. At the first deserializer 235 a, the first odd sub-data object and the first even sub-data object may be combined to output the first data object to the first read requester. At the second deserializer 235 b, the second even sub-data object may be combined with the second odd sub-data object to output the second data object to the second read requester.

FIG. 3 illustrates a timing chart 300 of the flow of the data objects through the module 115, according to an embodiment. Reference number 350 points to the write operation portion of the write/read of the data objects. Reference number 360 points to the read operation portion of the write/read of the data objects. For the write operation 350, at time t0, a first write operation may send a first data object 305 a to the module 115 and a second write operation may send second data object 305 b at the substantially the same time. The first write operation may come from a first sender 110 a (FIG. 1). The second write operation may come from a second sender 110 b (FIG. 1).

At time t1, the first data object 305 a and the second data object 305 b may both enter their respective first serializer 205 a and second serializer 205 b. The first serializer 205 a may divide the first data object 305 a into a first even sub-data object 310 a and a first odd sub-data object 315 a. For example, a 16 B data object may be divided into two 8 B sub-data objects. In other embodiments, the first serializer 205 a may divide the first data object 305 a into any number of sub-data objects. Also, the second serializer 205 b may divide the second data object 305 b into a second even sub-data object 310 b and a second odd sub-data object 315 b. In other embodiments, the second serializer 205 b may divide the second data object 305 b into any number of sub-data objects.

At time t2, the first even sub-data object 310 a may be written to a single port memory device that supports even sub-data objects. The second odd-sub data object 315 b may be written to a single port memory device that supports odd sub-data objects. In other embodiments, the timing of the second odd sub-data object 315 b may occur later. The second serializer 205 b may be delayed a half cycle from the first serializer 205 a and begin with the second even sub-data object 310 b being written at time t3 and then the second odd sub-data object 315 b being written subsequently.

At time t3, the first odd sub-data object 315 a may be written to a single port memory device that supports odd sub-data objects. The second even sub-data object 310 b may be written to a single port memory device that supports even sub-data objects. Alternating the sub-data objects as they are being written to the single port memory devices may avoid write collisions for data objects that arrive at the module at substantially the same time from independent senders.

Reference number 360 points to the read operation of the sub-data objects from the single port memory devices. The read operation may include two independent read requests from two read requesters. At time t4, the read controller 220 (FIG. 2) may receive a first read request from a first read requester for the first data object 305 a. The read controller 220 may also receive a second read request from a second read requester for the second data object 305 b. The read controller 220 may issue a first read command for the first data object 305 a and a second read command for the second data object 305 b. The odd and even single port memory devices may output the first even sub-data object 310 a of the first data object 305 a and the second odd sub-data object 315 b of the second data object 305 b during the a first half cycle of the read command. In other embodiments, there may only be one read requester, the timing of which is illustrated in FIG. 7.

At time t5, during the second half cycle of the read command, the read controller 220 may issue a command for the first odd sub-data object 315 a to be sent for the first data object 305 a from the odd single port memory 120 b. The second even sub-data object 310 b for the second data object 305 b may be sent from the even single port memory 120 a.

At time t6, the first even sub-data object 310 a and the first odd sub-data object 315 a may enter the first deserializer 235 a (FIG. 2) for the first read requester. The second even sub-data object 310 b and the second odd sub-data object 315 b may enter the second deserializer 235 b for the second read requester also at time t6.

At time t7, the first deserializer 235 a may output the first even and odd sub-data objects 310 a and 315 b concatenated as the first data object 305 a to the first read requester. Also at time t7, the second deserializer 235 b the second even and odd sub-data objects 310 a and 315 b concatenated as the second data object 305 a to the second read requester. Interleaving more than one data objects by breaking them apart and sending sub parts of each data object together and combining the appropriate parts again may avoid read collisions from a single port memory when there are two or more read requesters.

FIG. 4 illustrates a flowchart of a method 400 for avoiding write collisions in a single port memory device, according to embodiments of the disclosure. The method 400 may begin at operation 405. In operation 405, a first data object may be divided into a first even sub-data object and first odd sub-data object. In an embodiment, the first data object may result from a first write operation. The first write operation may be sent from a first data sender such as cache (L3 cache) or any other circuit source to a single port memory device such as SRAM or DRAM. In an embodiment, the first data object may be evenly split into the first even sub-data object and the first odd sub-data object. In other embodiments, how the first data object is divided, whether it be evenly or unevenly and how many times it is divided, e.g., thirds or fourths, may be contemplated. The division of the first data object may be done by a first serializer.

In operation 410, a second data object may be divided into a second even sub-data object and second odd sub-data object. In an embodiment, the second data object may result from a second write operation. The second write operation may occur from a second data sender such as cache (L3 cache) or any other circuit data object source to a single port memory device such as an SRAM or DRAM. In an embodiment, the second data object may be evenly split into the second even sub-data object and the second odd sub-data object. In other embodiments, how the second data object is divided, whether it be evenly or unevenly and how many times it is divided, e.g., thirds or fourths, may be contemplated. The division of the second data object may be done by a second serializer.

In operation 415, the first even sub-data object may be stored in the first single port memory device and the second odd sub-data object may be stored in the second single port memory device. In operation 420, the second even sub-data object may be stored in the first single port memory device and the first odd sub-data object may be stored in the second single port memory device. When writing the first and second odd sub-data object to a second single port memory device, the first and second data objects may be aligned so that writes of the first and second odd sub-data objects do not occur at the same time. In various embodiments, the first and second write operations may be aligned so that when the first even sub-data object is being written to the first single port memory device, the second odd sub-data object is being written to the second single port memory device. Likewise, when the first odd sub-data object is being written to the second single port memory device, then the second even sub-data object is being written to the first single port memory device.

FIG. 5 illustrates a block diagram of a module 500 on which the single port memory device is configured to avoid write collisions of data objects where the data objects are not divided into sub-data objects, according to embodiments Consistent with certain embodiments, the module 500 can be used as the module 115 of FIG. 1. The module 500 can be configured to operate without a serializer and without using sub-data objects. Regular bus width of the data objects may be used in module 500. Each of the data objects may be odd or even depending on the lowest order address bit. Also, the data bus may run at its regular data width and speed in module 500.

The various embodiments discussed herein, including those discussed in connection with FIGS. 2 and 5 may have different requirements on the specific type and amount of logic that is used. For instance, a first data sender 505 a, a second data sender 505 b, and the module 500 are illustrated in FIG. 5. The first data sender 505 a and the second data sender 505 b may include launch logic to allow for the logic of the module 500 to operate correctly. An example of the launch logic is shown in FIG. 6 and explained further below. The module 500 may include a first optional delay 510 a and a second optional delay 510 b that may be referred collectively as optional delay 510 herein. The module 500 may include a first write multiplexor 520 a and a second write multiplexor 520 b that may be referred collectively as write multiplexor 520. The module 500 may also include a plurality of single write port memories. Four single port memory devices are shown in FIG. 5 as an example, single port memory device 525 a, 525 b, 525 c, and 525 d. The single port memory devices may be referred to collectively as single port memory device 525 herein. The module 500 may also include a write controller 530 and a read controller 535. The module 500 may also include a first read multiplexor 540 a and a second read multiplexor 540 b, which may be referred to collectively as read multiplexor 540 herein.

The first data sender 505 a and the second data sender 505 b may be communicatively coupled with respective first optional delay 510 a and second optional delay 510 b of the module 500. The data senders 505 may include a modified launch logic that is further explained in FIG. 6. The launch logic may be used to ensure that the data transfers from the senders 505 arrive at the module 500 aligned in the same way. Each data transfer may contain a plurality of data objects. The data objects may alternate as even and odd data objects in the order they are to be sent to the single port memories. The data senders 505 may wait to transfer the data objects after both senders have the same number of data objects. Once the data transfers are received by the module 500 and aligned the same way, then they may be guaranteed by the optional delays to have the data objects arrive at the actual single port memory devices 525 differently aligned and at substantially the same time. For example, the optional delays 510 may ensure that one data sender 505 will send its even data objects to the single port memory devices 525 when the other data sender sends its odd data objects. The delay is optional because zero is a valid even number of delay. For instance, when both senders have the same amount of data objects to write, one sender may start immediately without a delay, while the other sender may be delayed by one data object.

The first and second optional delays 510 a and 510 b are communicatively coupled with an even multiplexor 520 a and an odd multiplexor 520 b, respectively. The even multiplexor 520 a may receive the even data objects and the odd multiplexor 520 b may receive the odd data objects from either data sender 505. The even multiplexor 520 a may be communicatively coupled to a first even single port memory device 525 a, and a second even single port memory device 525 b. The first even single port memory device 525 a (highest order bit addresses) may receive an upper half of the even data object and the second even single port memory device 525 b may receive a lower half (lowest order bit addresses) of the even data object. Likewise, the first odd single port memory device 525 c may receive an upper half of the odd data object and the second odd single port memory device 525 d may receive a lower half of the odd data object. In other embodiments, a double wide single port memory device may be used so that each single port memory device has the same width as the even or odd data object.

The data senders 505 may also in operable communication with the write controller 530. The write controller may receive write commands from the data senders 505. A write controller 530 may be communicatively coupled with each single port memory device 525 and may signal a write address and a write enable for the write address. The write controller 530 may be in sync for the upper half and lower half of the data object writes. The even pair of single port memory devices may be treated by the write controller 530 as one single port memory device. The odd pair of single port memory devices 525 may be treated by the write controller 530 as one single port memory device also.

FIG. 5 illustrates an embodiment of the read operation from the single port memories when there is a single read requester. The read controller 535 may be communicatively coupled with each single port memory device 525 and may signal a read address and read enable for the data objects within the single port memory device 525 when a read request is received from a read requester 550. The read requester 550 may be communicatively coupled to the read controller. The read controller 535 may signal for the upper half and lower half of the requested data object at substantially the same time. The even pair of single port memory devices may be treated by the read controller 535 as one single port memory device. Likewise, the odd pair of single port memory devices 525 may be treated by the read controller 535 as one single port memory device. The data objects may be signaled to a read circuitry 545 that may contain an upper read multiplexor 540 a for upper half data objects and a lower read multiplexor 540 b for lower half data objects. The upper half and lower half of the even data objects may be signaled together when requested. The two halves may be concatenated by being sent in parallel. Likewise, the upper and lower halves of the odd data objects may be signaled together when an odd data object is requested. The two halves may concatenated by being sent in parallel. In various embodiments the read circuitry 545 may be replaced with the read circuitry 230 of FIG. 2 when there are two or more read requesters.

Referring now to FIG. 9, FIG. 9 illustrates module 500 where there are two read requesters from the system. Specifically FIG. 9 illustrates the part of the module 500 that includes the read operations. The even single port memories 525 a and 525 b may be communicatively coupled to a first demultiplexor 902 a. The odd single port memories 525 c and 525 d may be coupled a second demultiplexor. When each pair of single port memories are read, the outputs of the upper half and lower half of the single port memories may be concatenated before reaching their respective demultiplexors 902 a and 902 b. The demultiplexors 902 may route the data objects to either the first data sender 910 a or second data sender 910 b depending on where the data object is destined to go. The read controller may control when the reads occur from the single port memories 525 and also the demultiplexors 902 of the read circuitry 904.

The first read requester 910 a and the second read requestor 910 b may request a read from the single port memories 525 a at substantially the same time. The first and second requesters 910 a and 910 b may have delay logic that ensures that there is not a read collision from two or more read requesters by alternating the odd and even data objects between the first and second read requesters. The delay logic may delay a request for a data object by one cycle for one of the requesters. One requestor may receive even data objects while the other receives odd data objects. In various embodiments, the read controller 906 may contain the receive logic so that when both requestors 910 a and 910 b request a data object at substantially the same time, the read controller 906 may direct the even data object be read for the first read requester 910 a while the odd data object is being read by the second data requester 910 b.

FIG. 6 illustrates exemplary launch logic 600 of a data sender 505, according to an embodiment. The launch logic 600 includes a data transfer logic 605, an EVEN status latch 610, an AND gate 615, an inverter 620, and a data transfer arbiter 630 that receives data bus requests 625. The data transfer logic 605 may be the logic that counts data objects and signals the data transfer arbiter 630 when the data bus is available. The data transfer logic 605 may signal the AND gate 615 with a logical one when the data bus is available to the module 500. The even status latch 610 may signal to the AND gate 615 a logical one when the data object sender 505 is at an even cycle such as 4:1 cycle. When the data bus is available and the sender 505 is at an even cycle then the data bus requests 626 may be granted by the data transfer arbiter 630 and sent to the module 500.

In certain embodiments, if there is an odd number of data objects, then at the optional delays 510 a data transfer with an odd number of data objects may be delayed to wait for one data object to start from an even data transfer to start on an even grid. In various embodiments, it may be possible to replace the even status latch 610 with an odd status latch in one of the data senders 505. This may allow the data objects being sent from the data senders 505 to be alternating between odd and even data objects without requiring the optional delay circuitry 510.

FIG. 7 illustrates a timing chart 700 of the flow of the data objects through the module 500, according to embodiments. Reference number 750 illustrates a write operation to the single port memories 525 of module 500 and reference number 760 illustrates a read operation from the single port memories 525 of module 500. The read operation illustrates a read request from a single read requester. At time t0, a first write operation with at least a first even data object 705 a and a first odd data object 707 a may be sent from a first data sender 505 a. A second write operation with at least a second even data object 705 b and a first odd data object 707 a may be sent from a second data sender 505 b at substantially the same time as the first write operation is sent from the first sender 505 a. The write operations may be sent to an optional delay 510.

At time t1, the optional delay 510 may delay one of the write operations so that an even data object from one write operation is not being written to a single port memory device at the same time as another even data object from another write operation. Likewise, the optional delay 510 may delay a write operation so that two odd data objects are not being written to a single port memory device at substantially the same time. In the example shown in timing chart 700, the second write operation may be delayed.

At time t2, the first even data object 705 a from the first write operation may be written to a single port memory device dedicated for even data objects. The second even data object 705 b may be delayed so that it is not written to the single port memory device at the same time as the first even data object 705 a.

At time t3, the second even data object 705 b may be written to the single port memory device dedicated for even data objects. Also at time t3, the first odd data object 707 a may be written to a single port memory device dedicated for odd data objects.

At time t4, the second odd data object 707 b may be written to a single port memory device dedicated for odd data objects. The delays may ensure that the data object writes to the same single port memory device occur at different times, which may avoid write collisions in the single port memory devices. In embodiments, each odd and even data object may split into separate single port memories dedicated for the lower and upper half of the data objects.

Referring now to the single read request from a single read requester to the single port memory devices referenced by reference number 760. At time t5, the read requester may make a request for the second even data object. The second even data object may have been divided into an upper half 710 a stored in the first even single port memory 525 a (FIG. 5) and a lower half 710 b stored in the second even single port memory 525 b. The read controller 535 may signal the single port memories containing the upper half 710 a and the lower half 710 b of the second even data object 705 b when there is a request. The single port memories may send the upper half 710 a at substantially the same time as the lower half 710 b.

At time t6, the upper half 710 a and the lower half 710 b may concatenated when sent in parallel. The concatenated halves may form the complete second even data object 705 b. The second even data object 705 b may continue on to the read requester.

FIG. 8 illustrates a flowchart for avoiding a write collision in a single port memory device in the module 500 of FIG. 5, according to embodiments. The method 800 may begin at operation 805. In operation 805, the module may receive a first write operation that has a first even data object and first odd data object from a first data sender.

In operation 808, the module may also receive a second write operation that has a second even data object and a second odd data object from a second data sender. The first write operation and the second write operation may be received by the module at substantially the same time and aligned the same.

In operation 810, the second write operation may be delayed so that the first even data object does not write to a first single port memory device at substantially the same time as the second even data object. The delay also ensures that the first odd data object does not write to a second single port memory device at substantially the same time as the second odd data object is written.

In operation 815, the first even data object may be written to the first single port memory device and the first odd data object may be written to the second single port memory device. Furthermore, the second even data object may be written to the first single port memory device and the second odd data object may be written to the second single port memory device.

While the invention has been described with reference to specific embodiments thereof, those skilled in the art will be able to make various modifications to the described embodiments without departing from the true spirit and scope of the embodiments. The terms and descriptions used herein are set forth by way of illustration only and are not meant as limitations. Those skilled in the art will recognize that these and other variations are possible within the spirit and scope of the embodiments as defined in the following claims and their equivalents. 

1-8. (canceled)
 9. A semiconductor chip, comprising: a module, comprising: a first single port memory device configured to store a first even sub-data object and a second even sub-data object, a second single port memory device configured to store a first odd sub-data object and a second odd sub-data object, and a serializer configured to: divide a first data object from a first write operation into a first even sub-data object and a first odd sub-data object, divide a second data object from a second write operation into a second even sub-data object and a second odd sub-data object, store, in a single write, the first even sub-data object to the first single port memory device and the second odd sub-data object to the second single port memory device when the first write operation and the second write operation occur substantially at a same time, and store, in a single write, the second even sub-data object to the first single port memory device and the first odd sub data object to the second single port memory device when the first write operation and the second write operation occur substantially at a same time.
 10. The semiconductor chip of claim 9, wherein the module is further configured to: introduce write delays such that storing the first and second even sub-data objects does not occur at a substantially same time and storing the first and second odd sub-data objects do not occur at a substantially same time.
 11. The semiconductor chip of claim 9, wherein the module is further configured to: receive from a first data sender the first data object and from a second data sender the second data object.
 12. The semiconductor chip of claim 11, wherein the first data sender and the second data sender are cache memories.
 13. The semiconductor chip of claim 9, wherein the module further comprises: a read controller configured to: receive a read request for the first data object from a first read requester; read the first even sub-data object from the first single port memory device; read the first odd sub-data object from second single port memory device at substantially a same time as reading the first even sub-data object; and add the first even sub-data object to the first odd sub-data object to obtain the first data object, which is sent to the read requester.
 14. The semiconductor chip of claim 9, wherein the module further comprises: a read controller configured to: receive a first read request for the first data object from a first read requester; receive a second read request for the second data object from a second read requester at substantially a same time as receiving the first read request; read the first even sub-data object from the first single port memory device; read the second odd sub-data object from the second single port memory device at substantially a same time as reading the first even sub-data object; read the first odd sub-data object from the second single port memory device; read the second even sub-data object from the first single port memory device at substantially a same time as reading the first odd sub-data object; combine the first even sub-data object and the first odd sub-data object to form the first data object; combine the second even sub-data object and the first odd sub-data object to form the second data object; and send the first data object to the first read requester and the second data object to the second read requester at substantially a same time.
 15. The semiconductor chip of claim 9, wherein the first even data object is written to the first single port memory device at substantially a same time as the second odd data object is written to the second single port memory device.
 16. The semiconductor chip of claim 9, wherein the single port memory device is a single port static random access memory (SRAM). 17-20. (canceled) 